Abstract
The competition between sulfate reducing bacteria and methanogens over common substrates has been proposed as a critical control for methane production. In this study, we examined the co-existence of methanogenesis and sulfate reduction with shared substrates over a large range of sulfate concentrations and rates of sulfate reduction in estuarine systems, where these processes are the key terminal sink for organic carbon. Incubation experiments were carried out with sediment samples from the sulfate-methane transition zone of the Yarqon (Israel) estuary with different substrates and inhibitors along a sulfate concentrations gradient from 1 to 10 mM. The results show that methanogenesis and sulfate reduction can co-exist while the microbes share substrates over the tested range of sulfate concentrations and at sulfate reduction rates up to 680 μmol L-1 day-1. Rates of methanogenesis were two orders of magnitude lower than rates of sulfate reduction in incubations with acetate and lactate, suggesting a higher affinity of sulfate reducing bacteria for the available substrates. The co-existence of both processes was also confirmed by the isotopic signatures of δ34S in the residual sulfate and that of δ13C of methane and dissolved inorganic carbon. Copy numbers of dsrA and mcrA genes supported the dominance of sulfate reduction over methanogenesis, while showing also the ability of methanogens to grow under high sulfate concentration and in the presence of active sulfate reduction.
Highlights
Estuarine and shallow shelf sediments are often characterized by high fluxes of nutrients, high loads of organic carbon and marine salinity, containing high sulfate concentrations and housing intensive bacterial sulfate reduction and methanogenesis
This study evaluated the regulatory effects of sulfate concentrations and microbial sulfate reduction on methanogenesis in the sulfate methane transition zone (SMTZ) of estuarine sediments using the Yarqon river estuary as a case study
Estuarine sediments represent only 0.7% of the total marine sediments area, they contribute 7–10% of oceanic emissions of carbon to the atmosphere (Bange et al., 1994; Abril and Iversen, 2002)
Summary
Estuarine and shallow shelf sediments are often characterized by high fluxes of nutrients, high loads of organic carbon and marine salinity, containing high sulfate concentrations and housing intensive bacterial sulfate reduction and methanogenesis. Co-existence of sulfate reduction and methanogenesis characterizes the coastal sediments of North Sea estuary This co-existence was suggested to be controlled by the fast sediment accumulation combined with high organic carbon loading (Egger et al, 2016). These studies and others have emphasized that the various redox processes can co-exist in natural environments and may be coupled in a way that changes the rates of production or consumption of chemical species. This process has been shown to consume up to 90% of the upward methane fluxes in marine sediments (Borowski et al, 1996; Valentine and Reeburgh, 2000)
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